Model

ABSTRACT

The present disclosure is directed to model figures of beings or objects, such as animate and inanimate objects. Animate objects include living beings, such as humans, animals, plants. Such models may comprise a wire frame formed of body segments movably connected with three-way, two-way and one-way joints. The frame may be wrapped with an additional wire. The joints may also include multi-axial joints.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to pending PCT Application No. PCT/US2012/62664 filed Oct. 31, 2012, which claims priority to pending US. Provisional Application No. 61/705,461, filed Sep. 25, 2012, pending U.S. application Ser. No. 13/473,073, filed May 16, 2012, and to pending U.S. application Ser. No. 13/286,866, filed Nov. 1, 2011, and to pending Chinese Application No. 201110461199.4, filed Dec. 28, 2011, all of which are incorporated herein by reference.

FIELD OF THE DISCLOSURE

The present disclosure is directed to models of beings or objects, such as humans or animals. More particularly, the present disclosure is directed to a model figure comprising a frame and joints. The present disclosure is also directed to a model figure comprising a frame with wire body segments movably connected with joints that allow movement about one or more axes.

BACKGROUND OF THE DISCLOSURE

Models are widely available in an assortment of shapes, styles, and colors to represent full-scale objects and/or living creatures. Human models are often used by artists and art students. Artists and art students often use human models to aid in drawing the basic human shape in a variety of poses. A commonly used artist model is made of wooden pieces representing human body segments that are held together by an internal elastic band or an internal wire not visible to an end user. Such a model, however, is often unable to stand on its own. Such models typically are supported in a standing position using a rod and base connected to the torso or using a base connected to the feet. Alternatively, such models may be supported in a vertical position by an overhead support structure. Such supports may prevent the model from achieving a variety of positions, such as a sitting position. Furthermore, the artist or art student must mentally edit out these supports in order to draw the human shape. In addition, the wooden segments are solid and opaque, preventing the artist from seeing the opposite side and preventing the artist from viewing the three-dimensional shape of the model. The wooden models also have simple wooden hands that are incapable of holding items. The model can remain stationary in some poses and the model cannot remain stationary in other posed depending on the location of the wooden segments with respect to one another. In addition, the elastic band may lack endurance and may break after a relatively short lifespan. Artist and art students may also use wooden models of animals, such as horses. These models have similar drawbacks.

Models may also be used as decorations, desk accessories, and for other purposes. Many of these models available today, however, have the same limitations as the art models. For example, many of the available models are not capable of being posed in a standing position unaided. Furthermore, many models have only limited or unidirectional movement of limbs. Thus, limiting the variety of poses they can achieve and reducing the life-likeness of those poses.

Wire models of humans or animals are also available and may have a number of drawbacks, such as requiring locking and unlocking separate joints to pose the model. This can be time consuming and prevent easy possibility in a variety of positions. Some animal wire models may include joints at locations that do not correspond to life-like locations or do not mimic life-like function, such joints are for functions like folding for transportation. Some wire models may include only uniaxial joints, thus having limited maneuverability. Additionally, some models may have joints that are not able to hold the model in positions.

Thus, a need exists for a model with movable segments. A need also exists for a model that can be easily arranged in and remain in a variety of positions, including unsupported upright/standing and sitting positions. A need also exists for a model whose three-dimensional shape can be viewed from all directions.

BRIEF SUMMARY OF THE DISCLOSURE

The present disclosure relates to models of living beings, such as humans or animals, as well as inanimate objects. The present disclosure also relates to models with an internal frame members formed of a first wire, an external frame or wire formed of a wrapped second wire, and joints to enable movement of the internal frame members.

Moreover, the disclosed models are lightweight, free-standing models that are able to remain stationary in a variety of poses unaided by a user or a support structure like a base and rod. Some unaided poses the disclosed models can achieve include standing, sitting, hand standing, and hanging from objects. The broad range of maneuverability of the models relates to the joints, which can be one-way, two-way and/or three-way joints. The unaided positioning of models relates to the spring elements or spacers within the joints that provide a cushion between parts of the joints and/or provide resistance within a joint. Thus, enhancing the ability of the body segments to maintain poses. The disclosed joints are also unlocked so that they enable or always allow movement. The models may include hands that are capable of holding objects. The models may also include extremities, such as hands or tails that are capable of bending. This further enhances the maneuverability of the models by allowing these extremities to communicate and/or be personalized by end users.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings that form a part of the specification and are to be read in conjunction therewith, illustrate by way of example and not limitation, with like reference numerals referring to like elements, wherein:

FIG. 1 is a front, perspective view of a first example of a wire model with two-way open joints;

FIG. 2 is a close up, perspective view of a two-way open joint and portions of body segments of FIG. 1;

FIG. 3 is an exploded, perspective view of the joint and body segments of FIG. 2;

FIG. 4 is a side view of a lower portion of the wire model of FIG. 1;

FIGS. 5A-5D are front, perspective views of an upper portion of the wire model of FIG. 1 with a head segment moved to various positions;

FIG. 6 is a front, perspective view of the wire model of FIG. 1 shown in an unaided standing position;

FIG. 7 is a front, perspective view of the wire model of FIG. 1 shown in an unaided seated position and including a first alternative hand segment;

FIGS. 8A-8I show schematic representations of the wire model of FIG. 1 in various positions;

FIG. 9 is a close-up, perspective view of a two-way closed joint and portions of body segments;

FIG. 10 is an exploded view of the joint and body segments of FIG. 9;

FIG. 11 is a front, perspective view of a second example of a wire model with two-way open joints and a wire wrapped frame;

FIG. 11A is a perspective view of the wire model of FIG. 11 in a leaning position;

FIG. 12 is a side view of a lower portion of the wire model of FIG. 11;

FIG. 13 is a front, perspective view of a third example of a wire model with two-way open joints, a wire wrapped frame, and wire wrapped joints;

FIG. 14 is a front, perspective view of a fourth example of a wire model with two-way and three-way open joints;

FIG. 15 is a close-up, perspective view of a three-way open joint and portions of body segments of FIG. 14;

FIG. 16 is an exploded, perspective view of the joint and body segments of FIG. 15;

FIGS. 17A-17H are exploded, perspective views of various segments of the wire model of FIG. 14;

FIG. 17I is a perspective view of a hand segment of the wire model of FIG. 14;

FIGS. 18A-18D are perspective views of a lower portion of the wire model of FIG. 14 showing a foot segment moved to various positions;

FIG. 19 is an exploded, perspective view of a first alternative three-way joint and portions of body segments;

FIG. 20 is an exploded, perspective view of a second alternative three-way joint and portions of body segments;

FIG. 21 is a front, perspective view of a fifth example of a wire model with two-way joints and three-way open joints and a wire wrapped frame;

FIGS. 22A-22D are perspective views of wire models of FIGS. 1 and 22 in various positions;

FIGS. 23A-23C show schematic representations of the wire model of FIG. 22 or portions thereof in various positions;

FIG. 24 is a perspective view of a first alternative multi-axial joint;

FIG. 25 is a perspective view of a second alternative multi-axial joint;

FIGS. 26-28 are perspective views of alternative multi-axial joints and portions of body segments;

FIG. 29 is a perspective view of an alternative two-way joint and portions of body segments;

FIGS. 30A-30D are close-up, perspective views of third through sixth alternative hand segments;

FIG. 31A is a close-up, perspective view of a seventh alternative hand segment;

FIGS. 31B and 31C are perspective views of first and second wire pieces, respectively, of the hand segment of FIG. 31A;

FIGS. 31D and 31E are assembled, perspective views of the hand segment of FIG. 31A prior to and subsequent to wrapping the second wire piece, respectively;

FIG. 32 is a side, perspective view a sixth example of a wire model, in the shape of a dog, including a frame of first wire, one-way and two-way joints and a second wire wrapped about the frame;

FIG. 33 is a side, perspective view of the frame of the wire model of FIG. 32;

FIGS. 34-36 are top, schematic representations of wire pieces forming head, torso and leg segments, respectively, of the wire model of FIG. 32;

FIG. 37A-37C shows schematic representations of the wire model of FIG. 32 in various positions;

FIG. 38 is a perspective view of an alternative one-way joint;

FIG. 39 is a schematic representation of a seventh example of a wire model, in the shape of a woman;

FIG. 40 is a schematic representation of an eighth example of a wire model in the shape of a tree; and

FIG. 41 is a schematic representation of a ninth example of a wire model in the shape of a bulldozer.

DETAILED DESCRIPTION

Referring to FIG. 1, exemplary first wire model 10 of a living being is shown. First model 10 includes frame 12 that provides structure to first model 10 and includes head body segment 14, chest body segment 16, pelvis body segment 18, two upper arm body segments 20, two forearm or lower arm body segments 22, two upper leg body segments 24, two lower leg body segments 26, two foot body segments 28, and two hand body segments 30. Each of body segments 14-30 represents body segments or body parts of a living being, such as a human. Body segments 14-30 are formed of a first wire including wire pieces, as discussed in detail below.

Head body segment 14 may be formed by two wire pieces 32 and 34 that define an enlarged/open portion 36 and an adjacent connection end 38. Wire piece 32 may be formed in a loop and disposed around wire piece 34 so that wire pieces 32, 34 are angularly offset. As a result, head body segment 14 is “open.” “Open” as used herein means an element has a central open space. Body segments may also be “see-through,” which as used herein means an element allows a viewer to see through the element and view the elements three-dimensional shape from all directions. Body segments may be “open” but not “see-through” as discussed in detail below. Wire pieces 32 and 34 may be connected, for example, by soldering. Body segments 16-28 may be similarly constructed.

In an alternative, example, head body segment 14 may be formed to include one or more facial feature such as for example, eyes, nose, ears, mouth, and hair. Such facial features may be formed of a bendable wire so that an end user can customize the position and thus the look of head body segment 14. As a result, model 10 is customizable by an end user.

Wire piece 34 includes loop 34 a nested within wire piece 32, integral crossed section 34 b, and integral connection end 38. Connection end 38 includes a pair of coaxial loops 40 (best shown and discussed with respect to FIG. 3). Thus, loop 34 a, crossed section 34 b and coaxial loops 40 are formed of single wire piece 34. Crossed section 34 b (See FIG. 2) is optional and adds structural rigidity to head body segment 14 (shown in FIG. 1).

Chest body segment 16 may be formed by multiple wire pieces 42 that are angularly offset so that chest body segment 16 is open similar to head body segment 14. Wire pieces 42 include integral connection ends 44. Connection ends 44 are located at the neck, shoulders and waist to form joints (as discussed below). Connection ends 44 include a pair of coaxial loops 46 (best shown in FIG. 3).

Referring again to FIG. 1, pelvis body segment 18 may be formed by multiple wire pieces 48 similar to head segment 14 so that pelvis body segment 18 is open. Wire pieces 48 include integral connection ends 50 that include coaxial loops 52. Connection ends 50 are located at the waist and hips to form joints (as discussed below).

Lower arm body segments 22 are each formed by separate wire pieces 54, 56 that are angularly offset so that lower arm body segments 24 are open. Wire piece 54 includes integral loop 54 a and integral connection end 58. Wire piece 56 also includes integral loop 56 a and connection end 60. Loop 54 a may be nested within loop 56 a. Connection ends 58, 60 include coaxial loops 58 a, 60 a (best shown in FIG. 3, with respect to connection ends 38 and 44). Upper arm body segments 20, upper leg body segments 24, and lower leg segments 26 are formed similar to lower arm body segments 22.

Referring to FIGS. 1 and 4, foot body segments 28 are each formed by separate wire pieces 62, 64, 66. Wire piece 62 includes integral loop 62 a shaped like a foot and integral connection end 68. Integral connection end 68 includes a pair of coaxial loops 68 a similar to connection end 38 (shown in FIG. 2). Wire piece 62 may be nested within looped wire pieces 64 and 66. Foot body segments 28 further include lower surface or bottom 70 that may be flat to enable model 10 (see FIG. 1) to stand on a flat surface with no additional support.

Referring again to FIG. 1, hand body segments 30 are each formed by single wire piece 70. Wire piece 70 forms integral separate fingers 72 and connection end 74 similar to connection end 38 (shown in FIG. 3). Connection end 74 is located at the wrist to form a joint (as discussed below). Fingers 72 enable hand segment 30 to hold small objects (as shown in FIG. 23D).

Each of frame body segments 14-30 is a support structure that acts as a “skeleton” and provides first model 10 with its basic shape. Each frame body segment 14-30 also provides integral connection ends like connection ends 38, 44 (shown in FIG. 3) that allow relative movement of body segments 14-30 with respect to one another, as discussed below. Unlike an actual human skeleton, however, frame 12 is not made of bones in the center of the body part it is supporting. Instead, each frame segment 14-30 is molded or formed in the open general shape of the body part is it representing. For example, as can be seen in FIGS. 1 and 4, frame foot body segment 28 is molded or formed in the general shape of a foot with central open space 75. Likewise, frame lower arm segments 22 are molded or formed in the general shape of forearms with central open space 75, and frame head segment 14 is molded or formed in the general shape of a head with central open space 75.

Referring to FIG. 1, alternatively, model 10 may include a one-piece torso segment rather than a two-piece torso segment including chest and pelvis body segments 16,18 (as shown). Additionally, model 10 may include one-piece limb body segments (i.e., arms and legs). However, such one-piece body segments decrease the maneuverability of model 10 over multi-part body segments.

Frame 12 can be made of any material capable of supporting model 10 and integrally forming loops and connection ends, such as wire 32 (shown in FIG. 1). Frame 12 may be formed only of wire in one example. “Wire” is defined here to be “a metal material with a cross-sectional area that is small in proportion to the length.” Wire is not limited to a circular cross-sectional shape and may be any shape such as for example rectangular, square, hexagonal, etc. By way of example, frame 12 can be made of metal (such as, for example, stainless steel, iron, copper, aluminum, epoxy coated steel, vinyl coated steel, steel with an anodized finish), plastic, composite (such as carbon fiber), or any other suitable material. Frame 12 can retain the color of the underlying material or it can be changed to another color by painting, dying, coating, or any other means capable of changing the color.

Referring again to FIG. 1, model 10 further includes neck joint 76, waist joint 78, two shoulder joints 80, two elbow joints 82, two wrist joints 84, two hip joints 86, two knee joints 88, and two ankle joints 90. Neck joint 76 movably couples head segment 14 to chest segment 16. Waist joint 78 movably couples chest segment 16 to pelvis segment 18. Shoulder joints 80 movably couple each upper arm segment 20 to chest segment 16. Elbow joints 82 movably couple each upper arm segment 20 to each corresponding lower arm segment 22. Wrist joints 84 movably couple each lower arm segment 22 to each corresponding hand segment 30. Hip joints 86 movably couple pelvis segment 18 to each upper leg segment 24. Knee joints 88 movably couple each upper leg segment 24 to corresponding lower leg segment 26. Ankle joints 90 movably couple each lower leg segment 26 to each corresponding foot segment 28. Joints 76-90 correspond to analogous human joints except that the “waist joint” 78 is a single joint that replaces the movement allowed by the spine or vertebra in a living human. Joints 76-90 may be uniform in size.

Referring to FIGS. 1-3, joints 76-90 may be two-way joints that allow movement about two axes, for example the X and Y axes. Joint 76 includes a biaxial element defining the X and Y axes, so that the X and Y axes are offset 90 degrees from one another. The biaxial element includes bracket 92, first hinge or fasteners 94, and second hinge or fasteners 96. Fasteners 94 form a first hinge pair and fasteners 96 form a second hinge pair. Bracket 92 defines pairs of openings 98 and 99. Openings 98 along with fasteners 94 define the Y axis. Openings 99 along with fasteners 96 define the X axis. First hinge pair or fasteners 94 movably couple connection end 44 to bracket 92 via coaxial loops 46 to allow connection end 44 and integral chest segment 16 (See FIG. 1) to move about the Y axis. Second hinge pair or fasteners 96 movably couple connection end 38 to bracket 92 via coaxial loops 40 to allow connection end 38 and integral head segment 14 (See FIG. 1) to move about the X axis relative to chest segment 16. When joined to bracket 92, coaxial loops 40, 46 define the X and Y axes and maybe thus angularly offset by about 90 degrees. Fasteners 94 and 96 may also be positioned approximately 90 from one another when installed.

Referring to FIG. 3, bracket 92 may be generally square shaped to define central open space C. Alternatively, bracket 92 may be any shape that provides the necessary function of supporting fasteners 94, 96 in the necessary orientation. Exemplary bracket shapes include rectangular, circular, oval, U-shaped, C-shaped, a pair of U-shaped brackets, or a pair of C-shaped brackets. Joints 76-90 may be “open” joints because bracket 92 has central open space C. In this embodiment, joints may also be “see-through.” Bracket 92 may be made of any material suitable for holding fasteners 94, 96. By way of example, bracket 92 may be made of metal or sheet metal (such as, for example, stainless steel, iron, copper, aluminum, epoxy coated steel, vinyl coated steel, steel with an anodized finish), plastic, or any other material capable of holding fasteners 94, 96.

In the example shown in FIGS. 2 and 3, each fastener 94, 96 may be a rivet installed on square bracket 92 over connection ends 38, 44 of frame body segments 14 and 16 (See FIG. 1) respectively. One or more alternative mechanical fasteners may be used instead of rivets, such as, for example, screws or nuts and bolts.

Fasteners 94, 96 may be made of any material suitable for installation on square bracket 92. By way of example, fasteners 94, 96 may be metal (such as, for example, aluminum, stainless steel, iron, copper, aluminum, epoxy coated steel, vinyl coated steel, steel with an anodized finish), plastic (such as, for example, polypropylene and ABS), or any other suitable material.

When fasteners 94, 96 are rivets, the rivets may be any combination of all solid rivets, all blind rivets, or a combination of solid and blind rivets. This configuration secures frame body segments 14, 16 to bracket 92 thereby movably coupling body segments 14, 16. Body segments 18-30 of model 10 are similarly movably coupled.

Referring again to FIGS. 2-3, factory head 94 a of each rivet 94 may be positioned on the outside of wire coaxial loops 46 and shop head 94 b of each rivet 94 may be positioned on the inside of square bracket 92. Factory head 96 a of each rivet 96 may be positioned on the outside of wire coaxial loops 40 and shop head 96 b of each rivet 96 may be positioned on the inside of square bracket 92.

Joint 76 also includes spring elements or pairs of spacers 100 located between factory heads 94 a, 96 a of fasteners 94, 96 and frame wire coaxial loops 46 and 40, respectively. Spacers 100 provide a cushion between fastener factory heads 94 a, 96 a and wire coaxial loops 46 and 40, respectively. Spacers 100 assist in resisting movement between wire coaxial loops 46, 40 and bracket 92, thus enhancing the ability of body segments 14, 16 (See FIG. 1) to maintain poses such as an unaided standing position. The amount of resistance may be determined by the material properties and dimensions of spacers 100.

Spacers 100 can be made of any material capable of cushioning or offering resistance within joint 76. Cushioning means spacers resist movement at the joints. Spring elements or spacers 100 provide a friction force and a spring force S (see FIG. 2) acting on loops 46, 40 to resist movement at joint 76. By way of example, spacers 100 may be made of metal (such as, for example, stainless steel, spring metal, iron, copper, aluminum, epoxy coated steel, vinyl coated steel, steel with an anodized finish), plastic (such as, for example, acetate or polyvinyl chloride) or any other suitable material. Spacers 100 may be ring-shaped, as shown in FIGS. 2 and 3 or any other shape capable of cushioning or offering resistance within joint 76.

Referring to FIGS. 1-3, joint 76 is exemplary of joints 78-90 in model 10. Thus, joints 78-90 are formed with bracket 92, fasteners 94 and 96, spacers 100, and connection ends, like connection portions or ends 38 and 44.

Referring to FIG. 1, since model 10 is a human being, it can be any size provided the proportions are recognizable as human. Moreover, as shown in FIGS. 1 and 5A dimensions (i.e, width W, height H and depth D) of model 10 body segments may be modified so that the physique of model 10 changes to represent, for example, a thinner, larger, or more athletic human. Optionally, foot segments 28 may be in larger than normal proportion to other body segments 14-26 and 30 to add stability at base of model for unaided standing positions.

Referring to FIGS. 5A-5D, movement of head segment 14 relative to chest segment 16 via movement of two-way neck joint 76 will now be discussed. Two-way neck joint 76 is exemplary of all of two-way open joints 78-90 (See FIG. 1) and is shown and described to illustrate the function of all two-way joints 78-90. Referring to FIGS. 2 and 5A, when head segment 14 moves in a forward direction F about the X axis, connection end 38 (See. FIG. 3) and integral head segment 14 rotate forward about fasteners 96. At the same time, square bracket 92 (See FIG. 2) and chest connection end 44 remain stationary.

Referring to FIGS. 2 and 5B, when head segment 14 moves in a backward direction B about the X axis, connection end 38 (See FIG. 3) and integral head segment 14 rotate backward. At the same time, square bracket 92 and connection end 44 (See FIG. 2) remain stationary.

Referring to FIGS. 2 and 5C, when head segment 14 moves in a right side direction R about the Y axis, bracket 92 rotates about fasteners 96 with respect to chest connection end 44, which remains stationary. At the same time, connection end 38 also remains stationary. Alternatively, chest segment 16 can be moved to the right about Y axis so that head segment 14 and bracket 92 remain stationary and connection end 44 moves with respect to the Y axis.

Referring to FIGS. 2 and 5D, when head segment 14 moves in a left side direction L about Y axis, bracket 92 rotates about fasteners 96 with respect to chest connection end 44, which remains stationary with respect to bracket 92. At the same time, connection end 38 remains stationary with respect to bracket 92. Alternatively, chest segment 16 can be moved to the left about the Y axis so that head segment 14 and bracket 92 remain stationary and connection end 44 moves with respect to the Y axis.

Referring to FIGS. 1, 5A, 5C, two-way neck joint 76 and two-way joints 78-90 are each capable of moving in four directions—forward F, backward B, right side R, and left side L—about two axes (the X axis and the Y axis). Compound movements are also possible, where relative movement at a joint occurs about two axes consecutively. For example, head segment 14 can be rotated in a forward direction about the X axis, and then rotated about the Y axis, thus increasing the number of poses that can be created by model 10. In an alternative example, model 10 may include a three-way joint at neck joint 76.

Referring to FIGS. 1 and 3, such range of movement in joints 76-90 and resistance by spacers 100, allows each body segment 14-30 to be positioned in numerous positions, enabling the model 10 to be configured in a variety of human-like poses. FIGS. 1 and 6 show model 10 in an unaided standing position. In the unaided standing position, model to is standing on its own unsupported and model is capable of remaining in a standing position. In FIG. 1, model 10 has each arm in different positions. One arm is generally straight and the other arm is generally bent at elbow joint 82.

In FIG. 6, model 10 is posed in an unaided standing position so that arm segments 20, 22 and hand segments 30 are aligned and near chest and pelvis segments 16, 18. Model to also has aligned upper and lower leg segments 24, 26. In this pose, it can be appreciated that waist joint 78 has sufficient resistance to support the weight of upper body segments including chest segment 16, head segment 14, upper and lower arm segments 20, 22 and hand segments 30. In this pose, it can be appreciated that ankle joints 28 have sufficient resistance 10 support the weight of model 10 thereabove. Knee and hip joints 88, 86 similarly support portions of model 10 thereabove.

In FIG. 7, model 10 is posed so that model 10 is in an unaided upright seated position on surface S. Model 10 has upper leg segments 24 in a crossed position. In FIG. 7, first alternative frame hand segments 30′ are modified so that hand segments 30′ are formed into a more general mitten shape rather than having fingers 72 (see FIG. 1).

Referring to FIGS. 8A-8I, schematic representations of model 10 are shown in various exemplary poses. FIG. 8A shows model 10 in a cross leg seated pose. FIG. 8B shows model 10 in a one leg standing pose on a surface S. Shoulder, elbow and wrist joints 80, 82, 84 have sufficient resistance to support the weight of arms in overhead position. Ankle joint 900 has sufficient resistance to support the weight of model 10 thereabove, and body parts can be adjusted to balance model 10 on one foot.

The broad range of maneuverability of model 10 is shown further in FIGS. 8C-8I. FIG. 8C shows model 10 in a leap pose. FIG. 8D shows model 10 in a split leg pose. FIG. 8E shows model 10 in a waving pose. FIG. 8F shows model 10 in a forward bending pose. FIG. 8G shows model 10 in a backward bending pose. Wrist and ankle joints 84, 90 have sufficient resistance to support the weight of model 10. Construction of model 10 with separate chest and pelvis segments 16, 18 with waist joint 78 therebetween allows for the maneuverability shown in FIG. 8G. FIG. 8H shows model 10′ in a seated, bent leg position with one arm down and one arm up. Model 10′ may include head segment 14′ formed of a non-metal material such as for example plastic, wood or the like. Such non-metal material may be formed over wire frame or connected thereto in any way known to those of ordinary skill in the art. FIG. 8I shows model 10″ in a seated, straight leg forward reach. Model 10″ may include foot segments 28″ formed of a non-metal material, such as for example plastic, wood or the like. Such non-metal material may be formed over wire frame or may be connected thereto in any way known to those of ordinary skill in the art.

In order to change model 10 from pose to pose, a user need not unlock any elements of model 10, as all joints are unlocked and are always capable of movement. In order to place model 10 in some poses such as the one legged standing position of FIG. 8B a user may need to balance model 10 thru trial-and-error until the body segments are positioned so that the model is balance on one foot. This iterative trial-and-error process is easier due to the joints being unlocked. Since joints offer resistance to movement due to spacers 100 (see FIG. 3), this allows each trial pose in the iterative process to be held or retained by the model unaided.

Referring to FIGS. 9 and 10, two-way closed joint 76′ is shown. Two-way closed joint 76′ is similar to joint 76 of FIGS. 2 and 3 except bracket 92′ of joint 76′ is solid and thus lacks open space C of joint 76. Joint 76′ also lacks spacers 100 (shown in FIG. 3), although spacers 100 can be used with joint 76′, if desired. Joint 76′ may be for use with model 10. Joint 76′ functions like joint 76 to allow for movement about the X and Y axes, as previously discussed. Bracket 92′ may be formed of sheet metal or any other material disclosed for forming bracket 92.

Referring to FIG. 11, second exemplary wire model 110 is shown. Model 110 is similar to model 10 of FIG. 1. Model 110 is shown in an unaided standing position with straight legs, one straight arm and one bent arm. Model 110 is posable in a variety of life-like positions as discussed with respect to model 10. FIG. 11A shows model 110 leaning against a device D, such as a computer monitor.

Referring again to FIG. 11, model 110 includes frame 112 with first wire forming body segments 114-130. However, model 110 further includes second wire 131 disposed around body segments 114-128.

Second wire 131 may be wrapped around each frame body segment 114-128 in such a way that it provides a general appearance of the corresponding body part of a living being, such as a human. For example, as shown in FIG. 12, wire 131 is wrapped around frame lower leg segment 126 in such a way that resulting lower leg segment 126 generally resembles the lower leg shape of a human being. Similarly, wire 131 is wrapped around frame foot segment 128 in such a way that the resulting foot segment 128 generally resembles the foot shape of a human being. Additionally, wire 131 may be wrapped with gaps “g” that may be present between wire 131, and as a result body segments 114-128 and model 110 are “see-through.” In an alternative embodiment, second wire 131 may be wrapped to minimize or eliminate the gaps “g” so that some or all of body segments 114-128 are no longer “see-through.”

In addition, model 10 may further include a covering over the body segments 118-130 and/or the joints so that one or both are no longer “see-through.” Such covering may be wrapped filaments of yarn, plastic or composite, plastic simulated skin, or clothing of, for example, fabric.

Referring to FIG. 12, second wire 131 is wrapped around each frame foot segment 128 in such a manner that bottom surface 170 remains flat, enabling model 110 (See FIG. 11) to stand on a flat surface with no additional support. As shown in FIG. 11, frame hand segments 130 remain free of second wire 131 to allow fingers 172 to hold small objects (as discussed below). Joints 176-190 are not wrapped with second wire 131.

Wire 131 can be wrapped around frame body segments 114-128 by any means capable of disposing wire 131 therearound. By way of example, second wire 131 can be wrapped by hand or by machine or by a combination of the two.

Second wire 131 may be comprised of any number of wire segments. For example, second wire 131 may be one continuous wire that is wrapped around all of body segments 114-128. Second wire 131 may include several wire segments, each of which is wrapped around separate internal frame body segments 114-128. Second wire 131 may also be several wire segments and more than one wire segment may be wrapped around each body segment 114-128. Second wire 131 may be connected to first wires of frame 112 by, for example, soldering second wire 131 to frame 112.

As shown in FIG. 11, first wires, such as exemplary first wires 132, 142, and 154, forming frame 112 are thicker than second wrapping wire 131. As a result, frame 112 provides structural support and wire 131 may be more easily bent than first wire 132, 142, and 154.

Second wire 131 can be made of any material capable of wrapping around frame 112. By way of example, second wire 131 can be made of metal (such as, for example, stainless steel, iron, copper, aluminum, epoxy coated steel, vinyl coated wire), plastic, or any other suitable material. Second wire 131 can retain the color of the underlying material or it can be changed to another color by painting, dying, coating, or any other means capable of changing the color.

Referring to FIG. 13, third exemplary wire model 210 is shown. Model 210 is similar to model 110 of FIG. 1. Model 210 is shown in an unaided standing position like model 110. Model 210 is posable in variety of life-like positions as discussed with respect to model 10.

Model 210 is like model 110 except model 210 includes second wire 231 disposed around joints 276-290. Second wire 231 can be form by the same methods and of the same materials, as discussed with respect to second wire 131 (as shown in FIG. 11).

Referring to FIG. 14, fourth exemplary wire model 310 is shown. Model 310 is similar to model 10 of FIG. 1, and includes two-way joints located at neck joint 376, shoulder joints 380, hip joints 386, and knee joints 388. Two-way joints 376, 380, 386 and 388 are configured and function as previously discussed with respect to model 10. Model 310 is different from model 10 of FIG. 1 because model 310 includes three-way open joints located at waist joint 378, elbow joints 382, wrist joints 384, and ankle joints 390. Three-way joints 378, 382, 384, 390 allow movement about three axes, for example the X, Y, and Z axes.

Referring to FIGS. 14 and 15-16, three-way joints 378, 382, 384, and 390 will now be discussed in detail with respect to ankle joint 390. Three-way ankle joint 390 is similar to two-way joint 76 (shown in FIGS. 2-3) except connection end 338 has been modified and second bracket 301 has been added. Joint 390 includes first bracket 392, second bracket 301, connection end 338 (of lower leg segment 326 in FIG. 14), first fasteners 394, and second fasteners 396.

Second bracket 301 may be U-shaped or horseshoe-shaped and defines opening 303 perpendicular to openings 398 and 399. Opening 303 defines the Z axis. Second bracket 301 also defines openings 304 coaxial with the X axis and openings 399, when assembled. Connection end 338 of lower leg segment 326 may be bent so that loops 338 are also coaxial with the Z axis. Additional pivot or third fastener 305 movably couples lower leg segment 338 to second bracket 301. Joint 390 also includes spacer 306 disposed between fastener 305 and connection end 338. Spacer 306 may be similar to spacers 100 (in FIG. 3) and functions in the same way to provide resistance for maintaining poses. Spacer 306 can be made of any material previously discussed with respect to spacers 100 (in FIG. 1).

Fastener 305 may be a rivet or other fastener as previously discussed with respect to fasteners 94, 96 (in FIG. 3). Fastener 305 may also be installed as previously discussed with respect to fasteners 94, 96 (of FIG. 2-3). Second bracket 301 may be made of the same material discussed with respect to bracket 92 (in FIG. 3).

Referring to FIG. 14, three-way waist joint 378 is similar to ankle joint 390. However, waist joint 378 may be oriented in model 310 so that second bracket 301′ is below square bracket 392, however the opposite orientation may also be used. Three-way elbow joints 382 and wrist joints 384 may be oriented in model 310 like ankle joint 390.

Referring to FIG. 14 and FIGS. 17A-17I, frame 312 of model 310 has been modified to among other things minimize wires or wire bends, increase the range of motion at hip joints 386, and to accommodate 3-way joints 378, 382, 384, and 390. Modified frame 312 of model 310 will now be discussed in detail. Frame 312 may be configured to include “open” body segments 314, 316, 318, 320, 322, 324, 326, 328 and 330.

Frame head body segment 314 includes two pieces of wire 332 and 334. Wire piece 334 includes integral connection end 338 that forms part of neck joint 376, as previously discussed with respect to wire piece 34 (See FIG. 1) Wire piece 332 may be exterior to wire piece 334.

Referring to FIGS. 14 and 17B, frame chest segment 316 may include five pieces of wire 342 a, 342 b, 342 c, 342 d and 324 e. Wire piece 342 a may be a loop. Wire piece 342 b may be bent to include two integral connection ends 342 b′ and 342 b′ that form part of shoulder joint 380. Wire piece 342 c may include integral loop and integral connection end 340. Connection end 340 may form part of neck joint 376. Wire piece 342 d may be bent to include integral connection ends 342 d′ and 342 d′ that may form part of shoulder joint 380 and waist joint 378, respectively. Connection ends 342 b′ and 342 d′ cross to form part of shoulder joint 380. Wire piece 342 e may be bent to include integral connection ends 342 e′ and 342 e′ that may form part of shoulder joint 380 and waist joint 378, respectively. Connection ends 342 b′ and 342 e′ cross to form part of shoulder joint 380. Connection ends 342 d′ and 342 e′ cross to form part of waist joint 378.

Referring to FIGS. 14 and 17C, frame lower leg segment 326 may include two pieces of wire 326 a and 326 b. Wire piece 326 a is similar to wire 54 in forearm segment 22 (in FIG. 1) and includes integral connection ends 326 a′ as previously discussed with respect to forearm segment 22. However, wire piece 326 a may also include notched section 326 a′ configured to avoid fastener 305 (as best seen in FIG. 15) which is part of three-way ankle joint 390. Additionally, wire piece 326 b may include integral coaxial loops 340 (see FIG. 16) coaxial with the Z axis for connection to three-way ankle joint 390, as previously discussed with respect to FIGS. 15-16. The upper end of wire piece 326 b may be nested so as to be interior to connection end 326 a′. The lower end of wire piece 326 a including notched section 326 a′ may be nested so as to be interior to coaxial loops 340.

Referring to FIGS. 17D and 17E, upper arm segment 320 and lower arm segment 322 may each be formed of two wire pieces similar to lower leg pieces 326 a and 326 b, previously discussed with respect to FIG. 17C.

Referring to FIG. 17F, upper leg segment 324 may be formed like forearm segment 22 previously discussed with respect to FIG. 1. Upper leg segment 324 may be formed of two wire pieces 324 a and 324 b. Wire piece 324 a includes integral connection end 324 a′ and curved end 324 a′. Wire piece 324 b includes integral connection end 324 b′ and curved end 324 b′. Curved end 324 b′ may be nested so as to be interior to connection end 324 a′ and curved end 324 a′ may be nested so as to be interior to connection end 324 b′.

Referring to FIGS. 14 and 17G, pelvis segment 318 may be formed similar to pelvis segment 18 (shown in FIG. 1) except first wire piece 348 a includes notched section 348 a′ similar to lower leg wire section 326 a′ to avoid fastener 305′ of waist joint 378. Additionally, second wire piece 348 b has been modified to have a more oval shape to allow less interference of range of motion of the leg via hip joints 386 (see FIG. 14). Second wire piece 348 b has been further modified to include the connection end having coaxial loops 348 b′ to allow movement about the Z axis (as previously discussed). Third wire piece 348 c may be like similar wire 48 in pelvis 18 (in FIG. 1). Connection ends 348 a′ and 348 c′ form part of hip joints 386.

Referring to FIGS. 14 and 17H, foot segment 328 may be formed of three wire pieces 362, 364, and 366, similar to wire pieces 62, 64, and 66 (See FIG. 1). Wire piece 362 may includes flat segment 362 a and wire piece 366 includes flat segment 366 a. Flat segments 362 a and 366 a allow flat bottom of foot segment to be achieved. Referring to FIG. 17I, hand segment 330 may be formed like hand segment 30 of FIG. 1.

Referring to FIGS. 18A-D, movement of foot segment 328 relative to lower leg segment 326 via movement of three-way ankle joint 390 will now be discussed. Referring to FIGS. 16 and 18A, when foot segment 328 moves in forward direction F about the X axis, bracket 392 and connection end 344 along with connected foot segment 328 rotate forward about fastener 396. At the same time, second bracket 301 and connection end 338 remain stationary.

Referring to FIGS. 16 and 18B, when foot segment 328 moves in backward direction B about the X axis, bracket 392, connection end 344 along with integral foot segment 328 rotate backward about fastener 396. At the same time, second bracket 301 and connection end 338 remain stationary.

Referring to FIGS. 16 and 18C, when foot segment 328 moves in right side direction R or left side direction L about the Y axis, connection end 344 along with integral foot segment 328 rotate about fasteners 394. At the same time, connection end 338 and second bracket 301 remain stationary.

Referring to FIGS. 16 and 17D, when foot segment 328 rotates in inside direction C1 or outside direction C2 about the Z axis, second bracket 301 along with coupled first bracket 392 and foot segment 328 rotate about fastener 305. The brackets 301 and 392 along with coupled foot segment 328 are capable of rotating 360 degrees or more in either inside direction C1 or outside direction C2 (about the Z axis). Essentially, foot segment 328 may be capable of continuously rotating around pivot 305 (the third or Z axis) and stopping at any point within or beyond the 360 degree revolution. Thus, three-way ankle joint 390 is capable of moving in six directions—forward F, backward B, right R, left L, inside C1, and outside C2—about three axes X, Y, and Z.

Compound movements are also possible, where relative movement at a joint occurs about more than one axis consecutively. For example, foot segment 328 can be rotated in forward direction F about the X axis, and then rotated about the Z axis, thus increasing the number of poses that can be created by model 310.

Referring to FIGS. 14-16, three-way ankle joint 390 is representative of all of the three-way open joints 378, 382, and 384. Thus, joints 378, 382, and 384 may be constructed and function like joint 390, previously described.

Such three-way movement allows model 310 be positioned in numerous human-like positions, as previously discussed with respect to model 10, as well as additional poses, discussed below, that utilize movement about the Z axis.

Referring to FIG. 19, second exemplary three-way waist joint 378 a is shown. Three-way joint 378 a is similar to joint 390 of FIGS. 15 and 16 and includes first and second brackets 392 a and 301 a. However, in joint 378 a ring-shaped spacers 300 (of FIG. 16) have been replaced by wavy spacers 300 a. Joint 378 a also lacks additional spacer 306 (of FIG. 16). In another example, an additional wavy spacer 300 a may be positioned between coaxial loops 338 a and rivet 305 a. Joint 378 a may be for use with model 310. Wavy spacers 300 a function like spacers 100 (of FIG. 16), except spacers 300 a provide resistance that can withstand thousands of cycles of joint movement. Wavy spacers 300 a may be formed of materials disclosed with respect to spacers 100 of FIG. 16. Wavy spacers 300 a may be any flexible material capable of retaining their shape under pressure, such as, for example, spring metal or spring steel (stainless or galvanized), plastic or composite plastics. Each wavy washer 300 a may exhibit a strength above 800 MPa or more specifically 840 MPa to 860 Mpa. The amount of tensile strength necessary for a particular joint may depend on a number of factors including but not limited to the load on the joint, the material and configuration of the spacers, and the number of spacers used in the joint.

Wavy spacers or washers 300 a have an unloaded state and a loaded state. In the loaded state that occurs when spacer 300 a is installed similarly to spacer 100 as shown installed in FIG. 15, the installed thickness of washer 300 a is less than its unloaded thickness, but washer 300 a is not flattened completely when installed. As a result, in an installed state washer 300 a is compressed and exerts a spring force against adjacent structures to limit movement about the X and Y axis. Wavy washers 300 a are symmetrical so that they can be installed with surfaces 300 a′ or 300 b′ adjacent rivets 394 a or 396 a.

Referring to FIG. 20, third exemplary three-way waist joint 378 b is shown. Three-way joint 378 b is similar to joint 378 a of FIG. 19 except wavy spacers 300 a have been replaced by conical spacers 300 b. In another example, an additional conical spacer 300 b may be positioned between coaxial loops 338 b and rivet 305 b. Joint 378 b is for use with model 310. Conical spacers 300 b function like wavy spacers 300 a and exert a spring force at joint 378 a to resist movement. Conical spacers 300 b are not symmetrical and may be installed so that wider base 300 b′ of washer 300 b is adjacent square bracket 392 b. Conical spacers 300 b may be formed of materials disclosed with respect to spacers 100 of FIG. 16 or wavy spacers 300 a of FIG. 19.

The size of three-way waist joint 378 b relative to the size of the body segments may be increased or decreased depending on the strength needed at the joint. Moreover, all joints in model 310 (in FIG. 14) may be the same size or some joints (such as waist joint 378) may be larger than others to provide additional resistance in joints.

Referring to FIG. 21, fifth exemplary wire model 410 is shown. Model 410 is similar to model 310 of FIG. 14 except model 410 is wrapped with second wire 431, similar to second wire 131, as previously discussed with respect to model 110 (see FIG. 111). Model 410 is shown in an unaided standing position with straight legs, one straight arm and one bent arm. Model 410 may be further modified to include joints wrapped with second wire 431 as previously discussed with respect to model 210 of FIG. 13.

Referring to FIGS. 1, 11, 13-14 and 21, models 310 and 410 are posable like models 10, 110, and 210. However, models 310 and 410 can be placed in additional poses due to three-way joints 378, 382, 384, and 390. FIG. 22A shows model 410 posed in an unaided standing position with inward rotation of foot segments 428 about the Z axis (in FIG. 18D) associated with ankle joints 490.

FIG. 22B shows model 310 in an unsupported seated position on surface S with outward rotation of foot segments 328 about the Z axis (shown in FIG. 18D) associated with ankle joints 390. In addition, chest segment 316 and pelvis segment 318 are rotated relative to one another about the Z axis (shown in FIG. 18D) associated with waist joint 378.

FIG. 22C shows model 410 a posed like model 310 (as shown in FIG. 22B) with relative rotation at waist joint 478 a and ankle joints 490 a. Model 410 a includes a mitten shaped hand segment 430 a, as previously discussed with respect to FIG. 7.

FIG. 22D shows model 410 in a reclined sitting position on surface S. Model 410 is capable of remaining in a sitting position. Model 410 is bent backwards with hands 430 rotated about their associated Z axis and feet 428 rotated about their associated Z axis. In model 410, one hand 430 is holding piece of paper P between fingers 472. Fingers 472 are capable of holding any small object such as paper, stamps, business cards, greeting cards, brochures, or any other suitable object. Fingers may also be bent to hold pens and other objects. Models 10 (in FIGS. 1 and 6), model 110 (in FIG. 11), model 210 (in FIG. 13), model 310 (in FIGS. 14 and 23B), and model 410 (in FIGS. 21 and 22A) with separate fingers formed can similarly hold small objects.

FIG. 23A shows a schematic of model 410 in an unsupported handstand on surface S. In this pose, it can be appreciated that waist joint 478 has sufficient resistance to support the weight of lower body segments including pelvis P, legs L and feet F and the weight of the associated joints. In this pose, it can be appreciated that wrist joints 484 and elbow and shoulder joints 482, 480 have sufficient resistance to support the weight of model 410 thereabove. Model 410 in a handstand is balanced on hands 430. Flat edge (similar to surface 392′ of bracket 392 shown in FIG. 16) of first brackets 492 may offer an additional surface for balancing model 410 in an unaided handstand. Model 410 has sufficient resistance in joints to be posed in an unsupported or unaided one arm handstand also. Model 410 can also be posed in a headstand, where head segment 414 contacts surface S and one or both hands can assist in balancing model 410 in a headstand.

FIG. 23B shows a schematic of model 410 posed in a one-handed, hanging position from surface S. Wrist joint 484 has sufficient resistance to support the weight of model 410 therebelow without hand 430 moving with respect to lower arm 422 causing model 410 to fall. Model 410 has sufficient resistance in wrist joints 484 to be posed in a two-handed, hanging position. Model 410 has a sufficient resistance in elbow joints 482 to be posed in one or two-armed hanging positions from forearms that may simulate climbing. Model 410 has sufficient resistance in shoulder joints 480 to be posed in one or two-handed hanging positions from arms. Model 410 has sufficient resistance in ankle joints 490 to be posed in one or two-footed hanging positions. Model 410 has sufficient resistance in knee joints 488 to be posed in one or two-legged hanging positions with knees bent. Model 410 has sufficient resistance in hip joints 486 to be posed in one or two-legged hanging positions. Model 410 can also be posed so that the upper or lower portion of model 10 is hanging from surface S with a bend at waist joint 378. Model 410 can also be positioned in a lying down or kneeling position.

FIG. 23C shows a schematic of lower arm portions 422 of model 410 of FIG. 23B posed with a small object O, such as a pen, between hands 430. Object O may be spaced from surface S but may also contact surface S. Elbow joints 483 of FIG. 24B also have sufficient strength to hold small objects such as paper, pens, etc., balanced horizontally on hands 430 or forearms 422.

Referring to FIG. 24, exemplary three-way joint 578 is shown. Three-way joint 578 is similar to joint 390 (see FIG. 16) in that it provides movement about three axes including the X axis. However, joint 578 may include first and second U-shaped brackets 501 a and 501 b similar to bracket 301. Brackets 501 a, b are movably coupled by fasteners 596 similar to fasteners 396 (see FIG. 16). Brackets 501 a, b may include openings (not shown) for receiving fasteners 596 similar to fasteners 396 (see FIG. 16). Connection ends (not shown) of body segments similar to connection end 338 (shown in FIG. 16) are disposed within gaps G. Joint 578 may also include spacers 500 b, d in contact with fasteners 596 for offering resistance to relative movement of brackets 501 a, b about the X axis. Joint 578 may also include spacers 501 a, b for offering resistance to relative rotational movement of connection ends (not shown) and associated body segments (not shown) about axes Z1 and Z2. Spacers 500 a,b,c,d are wavy spacers like wavy spacers 378 a (of FIG. 19) but ring and conical spacers, as previously discussed, can also be used. Since there is movement about the X axis, the Z1 axis, and the Z2 axis, joint 578 is a three-way joint and can be used in models 10, 110, 210, 310, and 410 where such movement is desired. Brackets 501 a, b may be formed of the same materials as second bracket 301 (see FIG. 16).

FIG. 25 shows exemplary three-way joint 678 similar to joint 578 (see FIG. 24) except joint 678 includes leaf spring 600 a. Leaf spring 600 a may offer resistance to allow positioning of model as previously discussed and to withstand thousands of cycles of joint movement. Leaf spring may be designed to offer greater resistance compared to wavy washers, conical washers and ring-shaped washers previously discussed. Leaf spring 600 a may be adjusted to increase or decrease the amount of friction. For example, the friction can be increased when used as a waist joint such as waist joint 378 (see FIG. 14) as compared to the remaining joints so that waist joint 378 can support upper portion of model 310. Leaf spring 600 a may function similar to wavy washer 300 a (of FIG. 19) and is preferably formed of materials disclosed with respect to spacers 100 of FIG. 16.

Referring to FIG. 26, a first exemplary multi-axial joint 728 is shown. Multi-axial joint 728 is shown as an elbow joint for model 310 of FIG. 14, but multi-axial joint 728 may replace any joint 376, 378, 380, 384, 386, 388, 390 where movement offered by joint 728 is desired. Joint 728 allows upper arm segment 720 and lower arm segment 722 to move about at least axes X, Y and Z as shown by directional arrows D1, D2 and D3. Geometry of multi-axial joint 728 may also allow for circumduction, where upper arm segment 720 or lower arm segment 722 move relative to one another outlining a circle or a cone. Upper arm segment 720 includes open body segment 720 a like body segment 20 (FIG. 1) and includes post 702 b and ball 720 c. Body segment 720 a, post 702 b, and ball 702 c may be formed integrally or coupled by means such as welding. Lower arm segment 722 includes open body segment 722 a like body segment 22 (FIG. 1) and includes post 722 b and socket 722 c. Ball 720 c is preferably formed of steel and U-shaped socket 722 c may be formed of sheet metal and configured so that socket 722 c exerts a spring force on ball 720 c. Socket 722 c defines coaxial openings 722 d (one being shown) to hold ball 720C in place. Socket 722 c allows motion of joint 728 but also allows for resistance so that joint 728 aids in posing an associated model.

Alternatively, ball 720 c and socket 722 c may be formed of materials previously disclosed. For example, body segments 720 a, and 722 a may be formed of metal, wire or the like, socket 722 c may be formed of metal. Alternatively, body segments 720 a, 722 a may be formed of metal and ball 720 and socket 722 c may be formed of plastic using molding techniques know to those of ordinary skill in the art. The shape of socket 722 c may be changed to be, for example, spherical; however some other shape can also be used. Lower arm segment 722 may be further modified so that socket 722 c is separate from post 722 b and movably coupled thereto by a fastener that allows movement of socket 722 c thereabout, thus allowing for additional maneuverability of joint 728.

Referring to FIG. 27, a second exemplary multi-axial joint 828 is shown. Multi-axial joint 828 is similar to joint 728, except upper arm segment 820 includes U-shaped frame 820 a including integrally formed coaxial connection ends 820 b, post 820 c, ball 820 d, and cavity 820 e. Lower arm segment 822 is similarly constructed. Thus, upper and lower arm segments may have an open frame construction. Segments 820 and 822 may have the same features and may be formed of metal, such as steel. Connection end 822 a is configured to exert spring force around ball 820 d to hold ball 820 d in place and allow motion of joint 828 similar to joint 728 of FIG. 26. Coil spring 800 is disposed within cavity 822 b of segment 822 to increase spring or resistance force against ball 820 d to limit movement of joint 828 and aid in posing an associated model.

In the example shown, springs 800 have length L and are relatively thin. Springs 800 length L may be decreased so that springs 800 are shorter. Such shorter springs 800 may be formed of wire with an increased diameter for added spring force. Such smaller springs 800 may be located closer to ball 820 d. Such smaller thicker springs may be especially suited for, but are not limited to, waist joint 378 of model 310 (shown in FIG. 14).

Referring to FIG. 28, a third exemplary multi-axial joint 928 is shown. Multi-axial joint 928 is similar to joint 828, except coil springs 800 (of FIG. 27) have been replaced by rivet 900 and cylindrical spring 901 mounted adjacent to ball 920 d. Cylindrical spring 901 is shaped to exert a consistent spring force on ball 920 d when installed. Spring 901 increases spring or resistance force against ball 920 d to limit movement of joint 928 and aid in posing an associated model.

Referring to FIG. 29, an exemplary two-way joint 1028 is shown. Joint 1028 allows upper arm segment 1020 and lower arm segment 1022 to move about at least two axes X and Z as shown by movements X1 and Z1. Upper arm segment 1020 may include frame 1020 a with coaxial openings (not shown) for receiving shaft 1020 b. Connector 1021 is disposed between segments 1020 and 1022 and may be a U-shaped bracket like bracket 301 of FIG. 16. Connector 1021 includes coaxial openings (not shown) for receiving shaft 1020 b for movement about the X axis. Connector 1021 also includes opening 1021 b for receiving fastener 1023 similar to fastener 305 (of FIG. 16) for movement about the Z axis. Joint 1078 may also include coil spring 1000 welded or crimped to shaft 1022 b of segment 1022 and fastener 1023 to limit relative rotational movement Z1 of segments 1020 and 1022.

Referring to FIG. 1, hand segment 30 can be modified as discussed in detail below. Referring to FIG. 30A, a third exemplary configuration of hand segment 2030 is shown. Hand segment 2030 is similar to hand segments 30 (of FIG. 1) and is coupled to three-way wrist joint 2084 like three-way joint 390 (as shown in FIG. 16). However, hand segment 2030 b includes fingers 2072 a,b that may be bendable independently. Fingers 2072 a are shown in an exemplary straight position and fingers 2072 b are shown in an exemplary bent position.

Bendable fingers 2072 b allow models to be customized by the end user and may hold objects, communicate non-verbally, or have a unique look. Exemplary objects that may be held by bent fingers 2072 b include writing implements. Exemplary non-verbal communication may be sign language or other meaningful finger positions (as discussed below). Thus, models, such as model 10 of FIG. 1, having bendable features increases the maneuverability of model 10 and may allow model 10 to be personalized by the end user.

In one example, referring to FIGS. 30A and 1, the wire piece forming hand segment 2030 may be made of a material that is thinner than material that comprises wire of head segment 314, chest segment 316, pelvis segment 318, arm segments 320, 322, leg segments 324, 326, and foot segments 328. The thinner material of hand segment 2030 is capable of bending, and allowing the individual fingers 2072 a,b to bend independently of each other.

The thinner material may be any material capable of bending. For example, the thinner material may be stainless steel or aluminum. The thinner material may selected to allow the fingers to be bent a single time or repeatedly into different positions by a user. When a thinner material is used, the resistance at joint 2084 may need to be decreased so that an end user can grasp fingers 2072 a,b and rotate wrist joint 2084 without distorting fingers 2072 a,b.

FIG. 30B shows fourth exemplary bendable hand segment 3030 like hand segment 2030. Hand segment 3030 has fingers 3072 a bent to communicate non-verbally (i.e., the “peace” hand position). Furthermore, hand segment 3030 includes crossed-section 3030 a adjacent to wrist joint 3084. Such a configuration provides additional rigidity so that the thinner hand segment 3030 may be capable of easily moving with respect to lower arm body segment (not shown) without distorting the thinner wire forming hand segment 3030.

FIG. 30C shows a fifth exemplary bendable hand segment 4030 like hand segment 3030. Hand segment 4030 has fingers 3072 a bent to communicate non-verbally (i.e., the “I love you” hand position). Furthermore, hand segment 4030 may be formed of two pieces of wire 4030 a,b coupled by crimp 4030 c. Wire piece 4030 a may be bendable and includes bendable fingers 4072. In other examples, wire pieces 4030 a, b may be coupled by another device. Wire piece 4030 b includes integral connection end 4030 d for movably coupling wire piece 4030 a to wrist joint 4084 via crimp 4030 c. Such a configuration may assist in preventing distortion of thinner hand segment 4030 when moved with respect to lower arm segment (not shown).

Referring to FIGS. 30C and 30D, a sixth exemplary hand segment 5030 is similar to hand segment 4030 except wire piece 4030 b has been replaced by U-shaped bracket 5030 b similar to U-shaped bracket 301 (shown in FIG. 16). In addition, hand segment 5030 includes bendable wire piece 5030 a. In this example, U-shaped bracket 5030 b may be coupled to wire piece 5030 a by rivet 5030 c through connection end 5030 d integrally formed by wire piece 5030 a. Thus, wire piece 5030 a is movably coupled to wrist joint 5084 so that wire piece 5030 a can rotate about axis Z. A spacer as previously discussed may be included between connection end 5030 d and rivet 5030 c to offer resistance to movement about Z axis. The resistance at joint 5084 may need to be adjusted so that an end user can grasp hand 5030 and rotate wrist joint 5084 without distorting fingers.

In other examples, other mechanical fasteners may be used rather than rivet 5030 c. Such a configuration may assist in preventing distortion of thinner hand segment 4030 when moved with respect to lower arm segment (not shown).

Referring to FIG. 31A, a seventh exemplary hand segment 6030 similar to hand segment 2030 (of FIG. 30A) is shown. However, hand segment 6030 is formed of two pieces of wire 6032, 6034. As shown in FIG. 31B, pliable wire piece 6032 is bendable. First end 6032 a of piece 6032 may be bent to form four fingers 6036 and thumb 6038. Second end 6032 b of piece 6032 is wrapped about second wire piece 6034 (See FIG. 31A), as discussed below. As shown in FIG. 31C, wire piece 6034 is a wrist connector and defines opening 6040, and includes integral connection end 6042 for movably coupling wire piece 6034 to form wrist joint 2084 (as shown in FIG. 31A). Wire piece 6034 may also include optional crossed-section 6043 for increased rigidity.

Referring to FIGS. 31B-D, to construct hand segment 6030 four fingers 6036 are inserted through opening 6040 and thumb 6038 rests outside opening 6040. Once wire pieces 6032 and 6034 are joined, as shown in FIG. 31D, second end 6032 b of first wire 6032 is wrapped around lower portion of second wire 6034 below opening 6040 to below cross-section 6034 and the wrapped wire forms palmar surface 6044 and opposite dorsal surface (not shown). Thus, hand segment 6030 is wrapped so as to be partially no longer “see-through,” but fingers 6036 remain “see-through.” In the examples shown, second wire 6034 may be thicker than first wire 6032, facilitating bending of fingers 6036 (see FIG. 32E) and thumb 6038 while maintaining the shape of the hand. This configuration allows hand segment 6030 to move without distorting thinner first wire 6032. Alternatively, second wire 6034 may be thinner than first wire 6032 or first and second wires 6032, 6034 may be the same thickness.

Referring to FIG. 32, a sixth exemplary wire model 7010 of a living being is shown. Model 7010 is similar to model 10 of FIG. 1. Frame 7012 may include head body segment 7014, torso body segment 7016, tail body segment 7018, upper leg body segments 7020, lower leg body segments 7022, front foot body segments 7024 and rear foot body segments 7026. Frame 7012 is modified as compared to frame 12 of model 10 (see FIG. 1) so that frame 7012 simulates a dog. Modifications to frame 7012 will be discussed in detail below.

Referring to FIGS. 32 and 1, model 7010 is also similar to model 10 and includes two-way joints. In model 7010, two-way joints are located at neck joint 7027, hip joints 7028, and tail joint 7030. Two-way joints 7027-7030 may be configured and function as previously discussed with respect to model 10. However, model 7010 is of an animal, and more specifically a dog. In order to mimic a dog's movement, wire model 7010 further includes one-way joints located at shoulder joints 7032, elbow joints 7033, stifle or knee joints 7034, wrist joints 7037, and tarsus or ankle joints 7038.

Referring to FIGS. 32 and 33, modified frame 7012 of model 7010 will now be discussed. Frame 7012 may be configured to include “open” body segments 7012-7026. Frame head body segment 7014 may include two pieces of wire 7014 a and 7014 b. Wire piece 7014 a adds dimension to head segment 7014 and may be interior to wire piece 7014 b. Wire piece 7014 b may include integral connection end 7040 that forms part of neck joint 7027, as previously discussed with respect to wire piece 34 (See FIG. 1). Referring to FIGS. 33 and 34, wire piece 7014 b may be bent to also integrally include dog head features such as ears 7042, eyes 7044, snout 7046, nostrils 7048, and mouth 7050. Alternatively, model 7010 may include some but not all of such features.

Referring to FIG. 35, frame torso segment 7016 may include six pieces of wire 7052, 7054 (See FIG. 33), 7056, 7058, 7060, and 7062. Wire piece 7052 may extend generally front to back on upper surface of torso and may include integral connection loops 7052 a and 7052 b. Referring to FIG. 33, wire piece 7054 (See FIG. 32) may extend generally front to back on lower surface of torso and may include integral connection loops 7054 a and 7054 b (Shown in FIG. 35). Referring again to FIG. 33, wire piece 7052 may cross with wire piece 7054 forming part of neck and tail joints, 7027, 7030 (Shown in FIG. 32).

Referring to FIG. 35, wire piece 7056 may be bent to extend from integral connection loop 7056 a rearward along left side of torso 7016 across to the right side of torso and forward to connection loop 7056 b. Wire piece 7058 may be a closed looping element bent to extend generally widthwise across torso 7016 to connect right and left sides of torso 7016. Wire piece 7060 extends generally right to left at the rear of torso 7016. Wire piece 7060 may be bent to include integral connection loops 7060 a and 7060 b. Wire piece 7061 may be a looping element bent to include two integral connection loops 7061 a and 7061 b and extends generally widthwise across torso 7016 to connect right and left sides of torso 7016. Connection loops 7061 a and 7060 b and connection loops 7061 b and 7060 a form part of hip joints 7028 (See FIG. 33).

Referring to FIG. 35, at the front of torso 7016, wire piece 7062 may extend generally right to left. Wire piece 7062 may be bent to include integral connection loops 7062 a and 7062 b. Connection loops 7062 a and 7056 a and connection loops 7062 b and 7056 b form part of shoulder joints 7032 (See FIG. 33).

Referring to FIGS. 33 and 36, frame upper leg segment 7020 may include three pieces of wire 7064, 7065 and 7066. Wire piece 7064 may be bent to include two integral connection ends 7064 a that are oriented to be coaxial with the X axis and form part of shoulder joint 7032 and elbow joint 7033. Wire piece 7065 may be bent to include two integral connection ends 7065 a that are oriented to be coaxial with the X axis and form part of shoulder joint 7032 and elbow joint 7033. Wire piece 7066 may be a loop encircling central portions of wire 7064 and 7065. Fastener 7067 movably couples upper leg 7020 to connection ends 7056 a and 7062 a of torso 7016 (See FIG. 34) so that leg segment 7020 moves relative to torso 7016 about the X axis. Fastener 7068 movably couples upper leg 7020 to lower leg 7022 so that leg segments 7020 and 7022 move relative to one another about the X axis.

Referring to FIG. 36, frame lower leg segment 7022 may be formed similar to upper leg segment 7020 and is coupled to foot segment 7074 via fastener 7069 at wrist joint 7037 so that lower leg segment 7022 and foot segment 7074 move relative to one another about X axis. Joints 7032, 7033, and 7037 may include spacers S, as previously discussed, for limiting movement of segments so that model 7010 can remain stationary in poses. Their configuration may be dictated by the resistance desired at joints 7032, 7033, and 7037.

Referring to FIG. 34, the remaining legs of model 7010 may be similarly formed. Materials and methods used to form limbs of model 10 may be similarly used to form limbs of dog model 7010.

Referring to FIGS. 32-33 and 36, frame foot segments 7024, 7026 may each be formed of a single piece of wire to include integral toe segments 7070, forefoot portion 7072, adjacent rear foot portion 7074 and coaxial connection loops 7076.

Referring to FIG. 33, frame tail segment 7018 may include first piece of wire 7018 a and second piece of wire 7018 b connected thereto. First piece of wire includes integral coaxial connection loops 7018 c. This allows first and second pieces of wire 7018 a,b to be formed of wire of different gages. First piece 7018 a may be stronger than second piece 7018 b so that second piece 7018 b is bendable. Alternatively, tail segment 7018 may be formed of a single piece of wire or more than two pieces of wire. As a result, tail segment 7018 may be bent into a plurality of different positions. Thus, allowing model 7010 to express emotions or moods and allowing an end user to customize model 7010. Tail segment loops 7018 c are movably coupled to torso loops 7052 b and 7054 b (See FIG. 35) to form two-way tail joint 7030 (See FIG. 32).

Referring to FIG. 32, model 7010 is also similar to model 10 (of FIG. 11) in that body segments 7014-7024 may include an external second wire 7082 disposed around body segments 7014 and 7024 as described with respect to second wire 131 of FIG. 11. Second wire 7082 may be wrapped densely about tail segment 7018 in a series of spiraling loops so that frame tail segment 7018 b (see FIG. 33) is not visible thru second wire 7082. However, this wrapping may be less dense or may not include spiraling loops.

In FIG. 32, model 7010 is shown in an unaided standing pose. Model 7010 is posable in variety of life like positions as discussed with respect to model 10. Model 7010 may be positioned to assume a variety of typical dog positions, such as rear leg raised (as shown in FIG. 37A). In this position, the raised rear leg utilizes movement about the Y axis due to the two-way hip joint 7028. Alternatively, a front leg may be raised as in a “shake hands” pose or pointing pose. Model 7010 can balance on three legs.

Model 7010 may be positioned in a sitting pose (shown in FIG. 37B) that utilizes two-way joints 7028 for movement of its rear legs about X axis. Model 7010 may also be positioned in a stalking or crouched pose (shown in FIG. 37C), which utilizes movement of leg segments 7020 and 7024 about the X axis due to knee joints 7034. Model 7010 is also shown with tail segment 7018 bent. Model 7010 can also assume a plurality of additional poses, such as unaided standing on two rear legs, headstand with one or both forepaws, handstand on forepaws, hanging by one of more paws, hanging by tail. These postures are attainable by virtue of joints and spacers as previously discussed.

Referring to FIG. 32, wire model 7010 may also include two-way joints at one or more of shoulder joints 7032, knee joints 7034, and ankle joints 7072 for increased maneuverability. Alternatively, wire model 7010 may also include three-way or multi-axial joints in one or more locations.

Referring to FIG. 38, alternative one-way joint 8000 is shown. One-way joint 8000 may include two connection sections 8002, 8004 each with a plurality of fingers 8002 a, 8004 a for creating multiple friction surfaces in joint 8000. Fingers 8002 a and 8004 a define openings (not shown) for receiving fastener 8006 thus movably coupling sections 8002, 8004 for movement about the X axis. Joint 8000 may be formed so that fingers 8002 a, 8004 a exert a spring force on one another. Thus, joint 8000 may include optional spacers, as previously discussed, if desired for additional resistance. The manner of connecting connection sections 8002, 8004 to body segments of model 7010 depends on the materials selected for such components and conventional means may be used, such as welding, adhesive, injection molding, or casting.

Referring to FIG. 39, a seventh example of wire model 8110 is shown. Model 8110 is similar to model 10 of FIG. 1 except model 8110 is a woman. Model 8110 has head segment 8114 that has been modified to include wire wrapping 882 a to simulate hair. Model 8110 has chest segment 8116 whose frame 8116 a includes offset wire pieces and wire wrapping 8116 b supported thereon to simulate a female chest. Pelvis segment 8118 has been modified to be larger and more circular than model 10 (in FIG. 1) simulating a female pelvis. Model 8100 is shown in an unaided standing position. Model 8100 is posable in a variety of life-like positions, as discussed with respect to model 10.

Referring to FIG. 40, an eighth exemplary wire model 8410 of a living being or object in the shape of a tree is shown. Model 8410 is similar in concept to model 10 of FIG. 1. Model 8410 may include body segments such as trunk segment 8412, branch segments 8414, and leaf segments 8416 formed to resemble the corresponding parts of a tree. Trunk segment 8412, branch segments 8414 and leaf segments 8416 may be formed of internal frame and external wrap thereabout as previously discussed. Trunk segment 8412, branch segments 8414 and leaf segments 8416 are movably coupled by joint 8416. Segments 8412, 8414, and 8416 are formed in an open frame so that they have connection ends to operate in joints 8416 with resistance, as previously discussed. In addition, segments such as leaf segments 8416 may be formed of bendable wire so that they can be customized. Model 8410 is posable in a variety of life-like positions including an unaided upright position.

Referring to FIG. 41, a ninth exemplary wire model 8510 of a non-living being or an inanimate object in the shape of construction equipment (i.e., bulldozer) is shown. Model 8510 is similar in concept to model 10 of FIG. 1. Model 8510 may include numerous body segments including chassis segment 8512, wheel segments 8514, two front arm segments (one front arm segment 8516 being shown), front bucket segment 8518, rear arm segments 8520 a-c, and rear bucket segment 8524 formed to resemble the corresponding parts of a bulldozer. Such segments 8511-8522 may be formed of internal frame and external wrap thereabout, as previously discussed. Such segments 8511-8522 are movably coupled by one-way joints 8525, two-way joint 8526, and three-way joints 8528. However, joints 8525, 8526, 8528 may be modified to have a different combination of joint types. Segments 8511-8522 are formed in an open frame so that they have connection ends to operate in joints 8525-8528 with resistance, as previously discussed. In addition, segments (such as antenna segment 8530) may be formed of bendable wire like tail 7018 of FIG. 33 so that model 8510 can be customized by an end user. Model 8510 is positionable or posable in a variety of life-like positions including various elevated or extended unaided positions of front arm segments 8516, front bucket segment 8518, rear arm segments 8520 a-c, and rear bucket segment 8522.

Any model 10, 10′, 10′, 110, 210, 310, 410, 7010, 8110, 8410, 8510 may have a combination of one-way, two-way joints, three-way joints, multi-axial joints, open joints, and closed joints. In the human models, limiting the number of one-way joints allows for more maneuverability and life-like poses. In other examples, models may have only two-way joints, only two-way open joints, only three-way joints or only three-way open joints.

Referring to FIG. 10, closed bracket 92′ may be incorporated into any three-way joints replacing bracket 392 (of FIG. 16), bracket 392 a (of FIG. 19), and bracket 392 b (of FIG. 20). A particular joint may have no spring elements/spacers, one type of spring element/spacer, or a combination of two or more types of spring elements/spacers 100 (of FIG. 3), 300 (of FIG. 16), 300 a (of FIG. 19), 300 b (of FIG. 20, 600 a (of FIG. 26) depending on the resistance desired. The particular assemblies shown are for illustration purposes only and are not intended to limit the scope of the claims.

Various hand segments such as hand segments 30 (of FIG. 1), 30′ (of FIG. 7), 2030 (of FIG. 30A), 3030 (of FIG. 30B), 4030 (of FIG. 30C), 5030 (of FIG. 30D), and 6030 (of FIG. 31A) can be used with any model. Models may also include segments that are wrapped with second wire and segments that are unwrapped.

Although frame body segments are shown as including a particular number of wires in a particular configuration, another configuration with a different number of wires can be used that allows for the support function of the frame, allows for representing the appropriate body part and allows for operative association with the joints. Furthermore, the body segments can be divided into more or less segments than those shown. For example, torso may be divided into two or more segments. Similarly, pelvis, arms, legs, hands and feet can be divided into more segments than those shown.

Although models of humans and dogs are shown, models may also include other living beings such as other vertebrates like mammals (such as, for example, cats, elephants, giraffes, horses), birds, fish, amphibians, and reptiles; or invertebrates like worms and insects, (such as for example butterflies, flies, dragonflies). Additionally, models may also include extinct, mythical or fantastical living beings such as unicorns, dragons, dinosaurs, etc.). In addition, models may include living beings like plant life, such as for example, flowers and trees. Furthermore, models may include non-living objects like buildings, vehicles, machines such as for example cars, etc. Such models would have segments representing parts of such objects movably coupled by joints with resistance. Models may be modified to include features or accessories (like skirts of the male or female gender. Models may also be modified to represent baby or young living beings, such as for example children. Models may be modified to include bendable features for further customization.

Those skilled in the art will appreciate that the conception, upon which this disclosure is based, may readily be utilized as a basis for designing other products. Therefore, the claims are not to be limited to the specific examples depicted herein. For example, the features of one example disclosed above can be used with the features of another example. Thus, the details of these components as set forth in the above-described examples, should not limit the scope of the claims.

Further, the purpose of the Abstract is to enable the U.S. Patent and Trademark Office, and the public generally, and especially the scientists, engineers and practitioners in the art who are not familiar with patent or legal terms or phraseology, to determine quickly from a cursory inspection the nature and essence of the technical disclosure of the application. The Abstract is neither intended to define the claims of the application nor is intended to be limiting on the claims in any way. 

What is claimed is:
 1. A model of a figure comprising: first body segments made of wire and representing portions of the figure; and a first joint movably coupling said first body segments for movement about at least two different axes and for movement of said first body segments between a first pose and a second pose, said first joint further including a first resistance element for maintaining said first body segments in said first and second poses, said first joint not being locked whereby said model can move between and maintain said first and second poses without adjustment to said first joint.
 2. The model of claim 1, wherein said first pose is unaided standing.
 3. The model of claim 1, wherein said first pose is sitting.
 4. The model of claim 1, wherein each of said first body segments define a central open space.
 5. The model of claim 1, wherein said first joint further includes a bracket for defining said two different axes.
 6. The model of claim 1, further including a plurality of said first joints, wherein said first joints are two-way joints and said first joints are at first locations in said model.
 7. The model of claim 5, wherein said first joint further includes a first hinge and a second hinge; one of said first body segments further includes a first connection portion and the other of said first body segments includes a second connection portion; said first hinge being disposed through said first connection portion to movably couple said first connection portion to said bracket for movement about one of the axis; and said second hinge being disposed through said second connection portion to movably couple said second connection portion to said bracket for movement about the other of the axis.
 8. The model of claim 7, wherein said first connection portion is offset approximately 90 degrees from said second connection portion, and said first hinge is offset approximately 90 degrees from said second hinge.
 9. The model of claim 7, wherein said first hinge includes a first hinge pair; said second hinge includes a second hinge pair, and said first resistance element includes first and second pairs of spacers, said first pair of spacers being located between said first hinge pair said first connection portion, and second pair of spacers being located between said second hinge pair and said second connection portion.
 10. The model of claim 9, wherein said first connection portion is a pair of first loops and said second connection portion is a pair of second loops.
 11. The model of claim 1, wherein said first resistance element is a spacer.
 12. The model of claim 6, wherein said first locations include a neck location and hip locations.
 13. The model of claim 11, wherein the figure is a human.
 14. The model of claim 6, wherein said first locations further include shoulder locations and knee locations.
 15. The model of claim 6, wherein the figure is an animal.
 16. The model of claim 15, wherein said first locations include a neck location, hip locations, and a tail location.
 17. The model of claim 16, further including second body segments made of wire and representing portions of the figure, and said model further including a second joint located at a second location in said model, said second joint movably coupling said second body segments such that said second body segments move with respect to one another about only one axis.
 18. The model of claim 17, further including a plurality of the second joints located at a plurality of second locations, wherein said second locations include shoulder locations, knee locations, and ankle locations.
 19. The model of claim 1, wherein the figure is a non-living object.
 20. The model of claim 6, further including second body segments made of wire and representing portions of the figure, wherein said at least two different axes include a first axis and a second axis, and said model further including a second joint movably coupling said second body segments for movement about a third, fourth and fifth axes and for movement of said second body segments between a third pose and a fourth pose, said second joint being located at a second location within said model, and said second joint further including a second resistance element for maintaining said second body segments in said third and fourth poses; wherein said model can move between and maintain said third and fourth poses without further adjustment to said second joint.
 21. The model of claim 20, further including a plurality of the second joints at a plurality of second locations.
 22. The model of claim 21, wherein said first locations are a neck location, shoulder locations, knee locations, and hip locations, and said second locations are a waist location, elbow locations, wrist locations, and ankle locations.
 23. The wire model of claim 20, wherein said second joint further include a second bracket, a third bracket, a third hinge, a fourth hinge, and a fifth hinge, said third hinge movably coupling one of said second body segments to said second bracket for movement about said third axis, said fourth hinge movably coupling said third bracket to said second bracket for movement about said fourth axis, and said fifth hinge movably coupling the other said second body segment to said third bracket for movement about said fifth axis.
 24. The model of claim 1, wherein said first body segments include a pair foot segments, each of said foot segments including a flat bottom.
 25. The model of claim 1, wherein said first body segments include a pair of hand segments, each of said hand segments including fingers capable of holding an object.
 26. The model of claim 1, further including an external wire disposed around at least one of said first body segments.
 27. The model of claim 1, wherein said first body segments and said first joint are formed of metal.
 28. The model of claim 1, wherein one of said first body segments is a head body segment formed of plastic.
 29. The model of claim 25, wherein said first body segments further include a chest body segment and a pelvis body segment movably coupled by said first joint.
 30. The model of claim 1, wherein said first body segments include a pair of foot body segments, each of said foot body segments are formed of plastic.
 31. The model of claim 4, wherein said first body segments are formed of a first wire including a first wire piece and a separate second wire piece, said first wire piece including an integral first connection end and said second wire piece including an integral second connection end, said first and second wire pieces being angularly offset to define said central open space.
 32. The wire model of claim 1, wherein said first resistance element is selected from a group including ring-shaped spacers, conical-shaped spacers, and wavy spacers.
 33. The model of claim 1, wherein said first resistance element is selected from a group including metal, spring metal, plastic, acetate, or stainless steel.
 34. The model of claim 1, wherein one of said first body segments is bendable.
 35. A model of a figure capable of being positioned in various stationary poses, comprising: first body segments made of wire and representing differing body portions of the figure; and a first joint movably coupling said first body segments for movement about at least two different axes between a first stationary pose and a second stationary pose, said first joint further including a first resistance element for maintaining said first body segments in said first and second stationary poses; said first joint not being locked to permit said figure to move between and maintain said first and second stationary poses without adjustment to said first joint. 